KR20100133814A - Apparatus and method for managementing power of wlan module in portable terminal - Google Patents

Abstract

PURPOSE: A device and a method for managing power of a wireless LAN module in a portable terminal are provided to change a beacon cycle and a DTIM cycle according to active/sleep states of the portable terminal. CONSTITUTION: A portable terminal operates a WLAN(Wireless Local Area Network) module at a power saving mode(505). The portable terminal is converted into a sleep state(509). The portable terminal increases a beacon cycle and a DTIM(Delivery Traffic Indication Map) cycle. If a packet is received or a user inputs a signal, the portable terminal converts the sleep state into an active state(511,513). The portable terminal returns the beacon cycle and the DTIM cycle back to the original cycles.

Description

Method and device for power management of wireless LAN module in portable terminal {APPARATUS AND METHOD FOR MANAGEMENTING POWER OF WLAN MODULE IN PORTABLE TERMINAL}

The present invention relates to a power management method and apparatus for a wireless LAN module in a portable terminal, and in particular, changes the beacon interval and delivery traffic indication map (DTIM) cycle according to the state of the portable terminal to power the WLAN module. It relates to a method and apparatus for managing.

Recently, many portable terminals having a wireless LAN function for enabling a wireless network connection have been developed. The portable terminal connects to a wireless network through an access point (AP) that operates as a bridge and a router between the portable terminal and the network using a wireless LAN chip. As described above, the WLAN function is superior to other short-range wireless communication technologies in terms of communication speed, but data transmission between the WLAN and the AP may occur at any time, so the power of the WLAN module should be kept on at all times. Therefore, there is a problem that the current consumption is large.

Accordingly, in the related art, a power save mechanism (PSM) has been proposed to reduce power consumption due to the wireless LAN module of the portable terminal. 1 illustrates the power saving mechanism. As shown in FIG. 1, the portable terminal according to the power saving mechanism maintains the WLAN module in an awake state 103 based on a beacon interval 101 and then in a doze state. switching to (doze status or sleep status) 105, and exchanging a traffic indication map (TIM) / ACK packet during the awake state 103 when there is a packet to transmit and receive, The awake state 103 is maintained without switching to 105. For example, when the terminal A 111 has a packet to be sent to the terminal B 113, the terminal A 111 transmits a TIM packet in the awake state 103, and the terminal B 113 receiving the same also receives the awake state. By transmitting an ACK to the terminal B 113 at 103, data communication is performed by exchanging packets without switching to the doze state 105 later. On the other hand, the terminal C 115 does not have a packet to transmit and receive transitions from the awake state 103 to the doze state 105. Here, each terminal using the power saving mechanism, as shown in FIG. 2, periodically selects one beacon period in order to receive a multicast or broadcast packet, thereby awake state 103 in the beacon period. Keep it. Here, the selected beacon period is referred to as a delivery traffic indication map (DTIM) period. That is, the terminal does not switch to the doze state during the repeated DTIM interval in a fixed period, and keeps the awake state.

In general, when a portable terminal enters a sleep mode because no user input occurs for a predetermined time, that is, when a host processor enters a sleep mode, the probability of receiving a multicast or broadcast becomes very low. However, in the conventional portable terminal, the power saving mechanism of the WLAN is performed regardless of the state of the host processor, and thus a power consumption is unnecessarily consumed. For example, although the host processor of the portable terminal enters a sleep mode, the probability of receiving the multicast or the broadcast is very low, but the WLAN periodically maintains an awake state in the DTIM interval, thereby wasting power. There is a problem.

The present invention is derived to solve the above problems, an object of the present invention to provide a power management method and apparatus for a wireless LAN module in a portable terminal.

 Another object of the present invention is to provide a method and apparatus for managing power of a WLAN module provided in the portable terminal according to the state of the portable terminal.

Another object of the present invention is to provide a method and apparatus for reducing current consumption of a WLAN module by changing a beacon / delivery traffic indication map (DTIM) period according to an active / sleep state of a portable terminal. Is in.

According to a first aspect of the present invention for achieving the above object, a power management method of a wireless LAN module in a portable terminal, the process of operating the wireless LAN module according to a power save mechanism (Power Save Mechanism), and the portable Determining whether the terminal operates in a sleep state, and changing at least one of a beacon cycle and a DTIM cycle of the power saving mechanism according to whether the terminal operates in the sleep state.

According to a second aspect of the present invention for achieving the above objects, a power management apparatus of a wireless LAN module in a portable terminal includes a host process for detecting whether the portable terminal operates in a sleep state, and a power saving mechanism (Power And a wireless LAN module for changing at least one of a beacon period and a DTIM period of the power saving mechanism according to whether to operate in the sleep state.

The present invention has the effect of reducing the current consumption due to the WLAN module provided in the portable terminal by changing the beacon / DTIM period according to the active / sleep (active / sleep) state of the portable terminal.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings. In describing the present invention, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

Hereinafter, a description will be given of a technology for managing power of a wireless LAN module provided in the portable terminal according to an active / sleep state of the portable terminal. In the following description, an active / sleep state (or mode) of a portable terminal refers to an active / sleep state of a host processor that controls and processes the overall operation of the portable terminal. In addition, in the following description, the power saving mode refers to a mode in which the WLAN module repeatedly switches between the awake state and the doze state according to a conventional power save mechanism (PSM). Here, the awake state (or mode) refers to a state in which the WLAN module can transmit and receive packets by operating using a predetermined amount or more of power. By operating using this means that the packet transmission and reception is not made. In addition, in the following description, a beacon period is a period in which a period for TIM transmission and reception is repeated, and the WLAN module may be switched from an awake state to a doze state or continued in an awake state during the beacon period. The Delivery Traffic Indication Map (DTIM) period is a period in which a DTIM interval is repeated, and the DTIM interval refers to a period in which an awake state is maintained to receive a multicast or broadcast packet.

3 is a block diagram of a portable terminal according to the present invention.

Referring to FIG. 3, the portable terminal includes a host processor 310 and a WLAN chip 320.

The host processor 310 controls and processes the overall operations of the portable terminal, and performs a function of supplying power to the WLAN module 320 when an application using a WLAN is executed. In addition, the host processor 310 requests the WLAN module 402 to switch to a power saving mode operating according to a power saving mechanism (414). The host processor 310 controls and processes a function for entering the portable terminal into a sleep state when there is no user input or a packet received for a predetermined time, and sleeps to the WLAN module 402. Notifying the status entry to induce the beacon / delivery traffic indication map (DTIM) period of the WLAN module 402 is changed. In addition, the host processor 310 in the sleep state generates an input from the user or receives a wake-up signal from the WLAN module 320 to wake up from the sleep state and switch to the active state to process a corresponding operation. Perform

The WLAN module 320 receives power from the host processor 310, switches to a power saving mode at the request of the host processor 310, and switches the awake state and the doze state based on the beacon period. Do it repeatedly. In this case, the WLAN module 320 switches the awake state and the doze state according to a preset beacon period and a DTIM period in the power saving mode. In particular, the WLAN module 320 operates by changing the beacon cycle and the DTIM cycle in the power saving mode when a signal for entering the sleep state is input from the host processor 310. That is, when the portable terminal enters the sleep state, the WLAN module 320 changes the beacon period and the DTIM period long to minimize the time of operation in the awake state, thereby reducing the current consumption. Thereafter, the WLAN module 320 restores the changed beacon period and the DTIM period when the packet is received from the AP or a signal indicating the end of the sleep state is input from the host processor 310. Here, when a packet is received from the AP, the WLAN module 320 transmits a wakeup signal to the host processor 310 in the sleep state.

4 illustrates a signal flow of a host processor and a WLAN module in a portable terminal according to an exemplary embodiment of the present invention.

Referring to FIG. 4, if the execution of the application using the WLAN is detected in step 410, the host processor 400 proceeds to step 412 to supply power to the WLAN module 402, and in step 414, the WLAN module. Request 402 to switch to the power saving mode to operate. Upon receiving the request, the WLAN module 402 switches to the power saving mode in step 416 and repeatedly switches between the awake state and the doze state based on the beacon period. In this case, the WLAN module 402 switches the awake state and the doze state based on a preset beacon period and a DTIM period. For example, the WLAN module 402 switches the awake state and the doze state by setting the beacon period and the DTIM period to 100 ms and 300 ms, respectively.

In step 418, when the host processor 400 detects that a user input is not generated for a predetermined time, the host processor 400 proceeds to step 420, and enters a sleep state, and enters a sleep state to the WLAN module 402 in step 422. Inform. In operation 424, the WLAN module 402 increases the beacon period and the DTIM period in the power saving mode. For example, the WLAN module 402 switches the awake state and the doze state by changing the beacon period and the DTIM period set to 100 ms and 300 ms to 200 ms and 1000 ms, respectively. As described above, by increasing the beacon period and the DTIM period when the host processor 400 is in the sleep state, the time for the WLAN module 402 to operate in the awake state may be minimized.

After that, if it is detected in step 426 that the packet is input from the outside, the WLAN module 402 transmits a wake-up signal to the host processor 400 in step 428, and restores the beacon period and the DTIM period in step 430. do. For example, the WLAN module 402 restores the beacon period and the DTIM period set to 200 ms and 1000 ms to the preset values 100 ms and 300 ms to switch between the awake state and the doze state. Here, the steps 428 and 430 may be performed at the same time, the order may be changed. In this case, the host processor 400 receiving the wake-up signal ends the sleep state and switches to the active state.

Thereafter, the host processor 400 and the WLAN module 402 process the corresponding packet.

5 is a flowchart illustrating an operation procedure of a portable terminal according to an exemplary embodiment of the present invention.

Referring to FIG. 5, if the execution of the application using the WLAN is detected in step 501, the portable terminal proceeds to step 503 to supply power to the WLAN module, and in step 505, the WLAN module saves power. Operate with Here, the portable terminal allows the wireless LAN module to repeatedly operate the awake state and the doze state based on a preset beacon period and a DTIM period.

In step 507, the portable terminal detects whether a user input is not generated. If a user input occurs within the predetermined time, the portable terminal proceeds to step 517 to perform a task according to the user input, and returns to step 507.

On the other hand, when no user input is generated for the predetermined time, the portable terminal proceeds to step 509 to switch the portable terminal to a sleep state and notifies the WLAN module to increase the beacon cycle and the DTIM cycle. For example, when the WLAN module performs the power saving mode in the beacon period and the DTIM period set to 100ms and 300ms, the portable terminal changes and sets the beacon and DTIM period to 200ms and 1000ms, respectively.

Thereafter, the portable terminal checks whether a packet is received from the AP or the user input occurs. When the packet is received or a user input occurs, the portable terminal proceeds to step 513 to switch the portable terminal from the sleep state to the active state. Restore the increased beacon cycle and DTIM cycle. Thereafter, the portable terminal processes the corresponding operation, that is, the received packet or performs an operation according to a user input, and returns to step 507 to perform the following steps again.

In the above description, when the host processor of the portable terminal enters the sleep state, the beacon period and the DTIM period are changed to reduce the current consumption of the WLAN module. However, only one of the beacon period and the DTIM period may be changed. will be.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but various modifications may be made without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the scope of the following claims, but also by the equivalents of the claims.

1 shows a power saving mechanism;

2 is a diagram showing a relationship between a beacon and a DTIM;

3 is a block diagram of a portable terminal according to the present invention;

4 is a diagram illustrating a signal flow between a host processor and a WLAN module in a portable terminal according to an embodiment of the present invention; and

5 is a diagram illustrating an operation procedure of a portable terminal according to an embodiment of the present invention.

Claims (8)

In the power management method of a wireless LAN module in a portable terminal, Operating the WLAN module according to a power save mechanism; Determining whether the portable terminal operates in a sleep state; And changing at least one of a beacon period and a DTIM period of the power saving mechanism according to whether to operate in the sleep state. The method of claim 1, Changing at least one of the beacon period and the DTIM period, Increasing at least one of a preset beacon period and a DTIM period when the portable terminal operates in a sleep state; Restoring the increased period when the sleep state of the portable terminal is terminated. The method of claim 1, The process of determining whether the portable terminal operates in a sleep state, Determining that the portable terminal operates in a sleep state when no user input occurs for a predetermined time; And determining that the user does not operate in the sleep state when a user input occurs or an external packet is received during the sleep state. The method of claim 1, The power saving mechanism is a technique in which the WLAN module operates with a predetermined amount or more of power to transmit and receive packets, and operates with a predetermined amount or less of power, and repeatedly switches a doze state where packet transmission and reception are not performed. Way. In the power management device of a wireless LAN module in a portable terminal, A host process for detecting whether the portable terminal operates in a sleep state; And a WLAN module that operates according to a power save mechanism and changes at least one of a beacon cycle and a DTIM cycle of the power save mechanism according to whether to operate in the sleep state. The method of claim 5, The WLAN module may increase at least one of a preset beacon period and a DTIM period when the portable terminal operates in a sleep state, and restore the increased period when the portable terminal ends the sleep state. Device characterized in that. The method of claim 5, The host processor determines that the portable terminal operates in a sleep state when no user input occurs for a predetermined time, and generates a user input during operation in the sleep state or receives a packet externally from the WLAN module. When a signal is input to indicate that And determine not to operate in the sleep state. The method of claim 5, The power saving mechanism is a technique in which the wireless LAN module operates by a predetermined amount or more of the awake state capable of packet transmission and reception and a doze state in which the packet transmission and reception is not performed by repeatedly operating the packet. Features as a device.

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